| Attending to Scenes |
1 |
Parkhurst & Niebur |
What could over 1000 Internet users tell us about visual attention in natural scenes? |
| 2 |
Hamker |
A dynamic computational model of goal-directed visual perception |
| 3 |
Oliva, Torralba, Castelhano, & Henderson |
Top-down control of visual attention in real world scenes |
| 4 |
Özgen, Sowden, & Schyns |
I WILL use the channel I want: flexible spatial scale processing |
| 5 |
Maljkovic & Martini |
Different rates of memory formation for scenes with positive and negative affective content |
| 6 |
Vessel, Biederman, & Cohen |
How opiate activity may determine spontaneous visual selection |
| Spatial Vision |
7 |
Dao, Lu, & Dosher |
Adaptation to sine-wave gratings selectively reduces the sensory gain of the adapted stimuli |
| 8 |
Kontsevich & Tyler |
Origins of the nonlinearity near threshold |
| 9 |
Taylor, Bennett, & Sekuler |
Noise detection: bandwidth uncertainty and adjustable channels |
| 10 |
Klein & Levi |
External noise yields a surprise: What template? |
| 11 |
Dijkstra, Liu, & Oomes |
Perception of ellipse orientation: data and bayesian model |
| 12 |
Balas & Sinha |
STICKS: Image-representation via non-local comparisons |
| Space Perception |
13 |
Bridgeman, Dassonville, Bala, & Thiem |
What is stored in the sensorimotor visual system: map or egocentric calibration? |
| 14 |
Stankiewicz, McCabe, Kelly, & Legge |
Lost in virtual space: estimating state uncertainty |
| 15 |
Witt, Proffitt, & Epstein |
The role of effort and intention in distance perception |
| 16 |
Creem-Regehr, Willemsen, Gooch, & Thompson |
The effects of restricted viewing conditions on egocentric distance judgments |
| 17 |
Ni, Braunstein, & Andersen |
Interactions of motion parallax and ground contact in specifying distance in a 3-D scene |
| 18 |
Thompson, Gooch, Willemsen, Creem-Regehr, Loomis, & Beall |
Compression of distance judgments when viewing virtual environments using a head mounted display |
| Early Visual Processing |
19 |
Bonin, Mante, & Carandini |
Origins of size tuning in LGN neurons |
| 20 |
Repucci, Mechler, & Victor |
Linear and nonlinear orientation dynamics of receptive fields in cat area 17 |
| 21 |
Gur, Kagan, & Snodderly |
Orientation selectivity in V1 of alert monkeys |
| 22 |
Westover, Anderson, & DeAngelis |
A new quantitative analysis of simple cell space-time receptive fields |
| 23 |
Supèr, Spekreijse, & Lamme |
Transformation of perceptual activity into saccade-related activity in the monkey primary visual cortex. |
| 24 |
Peirce, Solomon, Forte, Krauskopf, & Lennie |
Chromatic tuning of binocular neurons in early visual cortex |
| Visual STM |
25 |
Alvarez & Cavanagh |
Visual short-term memory capacity for orientations is lower for oriented Gabors than for oriented lines |
| 26 |
Wright & Alston |
Limitations of visual memory in spatial frequency discrimination |
| 27 |
Xu & Nakayama |
Placing objects at different depths increases visual short-term memory capacity |
| 28 |
Droll, Hayhoe, Triesch, & Sullivan |
Task relevance of object features modulates the content of visual working memory |
| 29 |
Gajewski & Henderson |
Eye movements are cheaper than memory: evidence from a scene comparison task |
| 30 |
Williams, Henderson, & Zacks |
Incidental memory in visual search: both targets and rejected distractors leave a lingering trace |
| Multisensory Integration |
31 |
Banks & Ernst |
A biologically plausible model of cue combination |
| 32 |
Ernst & Jäkel |
Learning to fuse unrelated cues |
| 33 |
Shams, Tanaka, Rees, Iwaki, Shimojo, & Inui |
Visual cortex as a site of cross-modal integration |
| 34 |
Fujisaki, Shimojo, Kashino, & Nishida |
Recalibration of audiovisual simultaneity by adaptation to a constant time lag |
| 35 |
Somers & McNally |
Kinesthetic visual capture induced by apparent motion |
| 36 |
Sun, Campos, Chan, Zhang, & Lee |
Multisensory integration in self-motion |
| Attention Mechanisms |
37 |
Fallah, Stoner, & Reynolds |
Competitive selection of superimposed stimuli moving through space |
| 38 |
Mirabella, Samengo, Bertini, Kilavik, Frilli, Fanini, & Chelazzi |
Macaque area V4 neurons translate the attended features of a visual stimulus into behaviorally relevant categories |
| 39 |
Gottlieb |
The monkey's lateral intraparietal area: parallel representations and competitive mechanisms |
| 40 |
Luck, Vogel, Woodman, & Hyun |
Toward an embedded process metatheory of selective attention |
| 41 |
Burr, Verghese, Morrone, & Baldassi |
Search for motion direction: pop-out and set-size dependencies explained by stimulus and intrinsic uncertainty |
| 42 |
Vallines, Bodis-Wollner, Oezyurt, Rutschmann, & Greenlee |
Perisaccadic V1 activity is not due to shifting visuo-spatial attention |
| Natural Images |
43 |
Fowlkes, Martin, & Malik |
Ecological statistics of grouping by similarity |
| 44 |
Dastjerdi & Dong |
Independent component analysis of natural time-varying images under the constraint of the minimum time delay |
| 45 |
Dong, Simpson, & Weyand |
No suppression, only dynamic decorrelation: saccadic effects on the visual responses to natural time-varying images |
| 46 |
Zetzsche & Nuding |
Extra-classical receptive field properties: relation to natural scene statistics and development of nonlinear model structures |
| 47 |
Olman, Ugurbil, & Kersten |
Effects of image structure on perceived contrast and cortical activity in early visual areas |
| 48 |
Adelson |
Textural statistics and surface perception. |
| Binocular Vision |
49 |
Aslin, Jacobs, & Battaglia |
Depth-dependent contrast gain-control |
| 50 |
Blake & Sobel |
Motion prolongs perceptual dominance during binocular rivalry |
| 51 |
Lee, Blake, & Heeger |
Traveling waves of activity in V1 correlate with perceptual dominance during binocular rivalry |
| 52 |
Wilson |
A dynamical hierarchy of rivalry stages in vision |
| 53 |
White, Gao, & Zhou |
Fractal statistics of perceptual switching time series |
| 54 |
Kim, Grabowecky, & Suzuki |
Stochastic resonance in bistable binocular rivalry |
| Lighting and Shading |
55 |
Chien & Bronson-Castain |
Lightness constancy in 4-month-old infants: The effect of a local luminance ratio cue |
| 56 |
Rudd & Zemach |
The highest luminance anchoring rule in lightness perception: A counterexample and an alternative model |
| 57 |
Cornelissen, Wade, Dougherty, & Wandell |
fMRI of brightness perception |
| 58 |
Anderson & Winawer |
Layered image representations and the perception of lightness |
| 59 |
Hartung & Kersten |
How does the perception of shape interact with the perception of shiny material? |
| 60 |
Landy, Chubb, & Econopouly |
Blackshot: an unexpected dimension of human sensitivity to contrast |
| Stereo |
61 |
Cumming & Read |
Sensitivity to interocular delay in binocular V1 neurons |
| 62 |
Tanabe & Fujita |
Reduced binocular disparity selectivity of V4 neurons to anti-correlated random-dot stereograms |
| 63 |
McKee, Farell, & Verghese |
The cost of resolving stereo ambiguity |
| 64 |
Foulkes & Parker |
The effect of absolute and relative disparity noise on stereoacuity |
| 65 |
Petrov & Glennerster |
Disparity gradient between the target and its surroundings defines depth discrimination threshold |
| 66 |
Watt, Akeley, & Banks |
Focus cues to display distance affect perceived depth from disparity |
| Eye Movements - Cognitive |
67 |
Castelhano & Henderson |
Flashing scenes and moving windows: an effect of initial scene gist on eye movements |
| 68 |
Geisler, Perry, & Najemnik |
Visual search: Gaze contingent displays and optimal search strategies |
| 69 |
Caspi, Beutter, & Eckstein |
The accumulation of visual information driving the 1st saccade during visual search probed with spatiotemporal noise |
| 70 |
Körner & Gilchrist |
Target tagging in visual search |
| 71 |
Gersch, Kowler, & Dosher |
Dynamic allocation of visual attention during the execution of sequences of saccades |
| 72 |
Beintema, Van Loon, Hooge, & Van den Berg |
Saccadic decision-rate distributions reveal competition process |
| Shape and Depth |
73 |
Fleming, Torralba, Dror, & Adelson |
How image statistics drive shape-from-texture and shape-from-specularity |
| 74 |
Savarese, Li, & Perona |
Can we see the shape of a mirror? |
| 75 |
Nefs, Koenderink, & Kappers |
The influence of object orientation and shading on pictorial relief of Lambertian surfaces |
| 76 |
Ling & Hurlbert |
3D shape-colour interactions in a real object similarity task |
| 77 |
Rogers |
Depth and size scaling created by the differential perspective of ground plane surfaces |
| 78 |
Gillam & Grove |
A new kind of global stereopsis: The ability to determine slant or occlusion from patterns of horizontal disparity |
| 79 |
Vuong, Domini, & Caudek |
Flexible patches for recovering surfaces from binocular disparity |
| 80 |
Ghose, Hillis, Watt, Landy, & Banks |
Slant anisotropy and tilt-dependent variations in stereo precision |
| Biological Motion |
81 |
Grossman, Kim, & Blake |
Brain activity reflects perceptual learning of point-light biological motion |
| 82 |
Battelli, Cavanagh, & Thornton |
Biological motion perception is impaired in unilateral parietal patients |
| 83 |
Giese, Thornton, & Edelman |
Metric category spaces of biological motion |
| 84 |
Jastorff, Kourtzi, & Giese |
Role of learning in biological motion recognition |
| 85 |
Casile & Giese |
Critical features for biological motion |
| 86 |
Troje |
Gender and attractiveness from biological motion |
| 87 |
Jokisch, Troje, Kress, & Daum |
Inversion effects on the structural encoding and recognition of biological motion |
| 88 |
Jacobs & Shiffrar |
Multifaceted Vision: How Desert Ants Navigate - Mini Brains, Mega Tasks, Smart Solutions |
| Face Perception 1 |
89 |
Boutet, Collin, & Faubert |
Is there a relationship between the band of spatial frequencies critical for face recognition and configural encoding? |
| 90 |
Ostrovsky & Sinha |
Integration of low and high frequency information in facial recognition |
| 91 |
Nakayama |
Face specific processing: role of local features in an affine metric |
| 92 |
Gauthier, Tanaka, & Brown |
When misaligned faces are processed holistically |
| 93 |
Nederhouser, Mangini, Biederman, & Okada |
Invariance to contrast inversion when matching objects with face-like surface structure and pigmentation |
| 94 |
Goffaux, Jacques, Mouraux, Gosselin, Schyns, & Rossion |
Superstitious perceptions of a face revealed by non phase-locked gamma oscillations in the human brain |
| Motion and Depth |
95 |
Harris & Dean |
Perception of binocular 3-D motion: visual direction is more important than binocular disparity |
| 96 |
Uka & DeAngelis |
Task-specific contribution of area MT to stereoscopic depth discrimination |
| 97 |
Delicato & Qian |
Is depth perception of stereo plaids predicted by intersection of constraints, vector average or second-order features? |
| 98 |
Tyler, Likova, & Wade |
Widespread cortical specializations for disparate lateral motion |
| 99 |
Zanker & Zeil |
Analysing optic flow generated by locomotion through a natural environment |
| 100 |
Royden & Picone |
Simultaneous computation of heading and depth in the presence of rotations: A physiologically based model. |
| Face Perception 2 |
101 |
Meyers, Cox, & Sinha |
Neural responses to contextually defined faces |
| 102 |
Ganel, Goshen-Gottstein, & Goodale |
Isolating Face-Dependent and Face-Independent Processing of Expression and Direction of Gaze |
| 103 |
Duchaine, Butterworth, & Nakayama |
Normal object discrimination in a developmental prosopagnosic |
| 104 |
Sinha |
Face classification following long-term visual deprivation |
| 105 |
McKone & Gilchrist |
Faces versus expertise: Early maturity of face recognition in children |
| 106 |
Ng, Kaping, Webster, Anstis, & Fine |
Selective tuning of face perception |
| Cortical Organization |
107 |
Xu, Boyd, Gallucci, Thomas, Emeric, Barahimi, Stefansic, Shima, & Melzer |
Spatial frequency preference maps of primate visual cortex revealed by optical imaging of intrinsic signals |
| 108 |
Adams & Horton |
Cortical columns without a function |
| 109 |
Tjan, Lestou, Bülthoff, & Kourtzi |
An fmri method for identifying the sequential stages of processing in the ventral visual pathway |
| 110 |
Motter |
The cortical magnification factor for area V4 |
| 111 |
Whitney, Goltz, Thomas, & Goodale |
Flexible retinotopy: Motion dependent position coding in visual cortex |
| 112 |
Conner, Schwartz, Odom, & Mendola |
Monocular retinotopic mapping in amblyopic adults |
| Contours |
113 |
Martin, Fowlkes, & Malik |
Learning to optimally detect image boundaries using brightness, color and texture |
| 114 |
Schuetze, Niebur, & von der Heydt |
Modeling cortical mechanisms of border ownership coding |
| 115 |
Qiu & von der Heydt |
Interaction of border ownership and transparency in monkey visual cortex |
| 116 |
Gerbino & Volcic |
Revisiting Ebenbreite |
| 117 |
Verghese |
The costs and benefits of grouping along a contour |
| 118 |
Elder, Morgenstern, & Tabone |
The efficiency of contour grouping |
| 119 |
Norcia & Sampath |
What limits thresholds for contours in noise - contour response strength or uncertainty? |
| 120 |
Kellman, Garrigan, Kalar, & Shipley |
Good continuation and relatability: Related but distinct principles |
| 121 |
Tversky, Geisler, & Perry |
Contour grouping: is there something special about closed contours? |
| Visuo-motor Control |
122 |
Ma-Wyatt & McGraw |
Illusory positional shifts affect both perception and action |
| 123 |
Mennie, Hayhoe, Sullivan, & Walthew |
Look ahead fixations and visuo-motor planning |
| 124 |
Hayhoe, Aivar, Gaines, & Jovancovic |
Spatial memory use and coodination of eye, head, and hand movements. |
| 125 |
Medendorp, Goltz, Vilis, & Crawford |
Eye-centered remapping of remembered visual space in human parietal cortex |
| 126 |
Brouwer, Franz, & Thornton |
Grasping and representational momentum |
| 127 |
Franz & Scharnowski |
Grasp effects of visual illusions: dynamic or stationary? |
| 128 |
Goodale, James, Culham, Humphrey, & Milner |
FMRI confirmation of a neurological dissociation between perceiving objects and grasping them |
| 129 |
Trommershauser, Maloney, & Landy |
When uncertainty matters: the selection of rapid goal-directed movements |
| Special Session |
130 |
Gregory |
Phenomenal Phenomena Classified |
| Locomotion |
131 |
Enriquez, Andersen, & Sauer |
Static scene analysis for the perception of heading: landmark identity and position information |
| 132 |
Loomis & Beall |
Visual control of locomotion without optic flow |
| 133 |
Philbeck, O'Leary, & Lew |
Path integration precision is doubled by the imagined proximity of previewed landmarks |
| 134 |
Warren, Di, & Fajen |
Behavioral dynamics of avoiding a moving obstacle |
| 135 |
Fink, Foo, & Warren |
Mapping vision to action in the outfielder problem |
| 136 |
Legge, Mason, Brady, Giudice, & Schlicht |
Maplets: local geometrical components of human cognitive maps |
| Color |
137 |
Troscianko, Baddeley, Parraga, Leonards, & Troscianko |
Visual encoding of green leaves in primate vision |
| 138 |
Beer & MacLeod |
Color selectivity in metacontrast: asymmetrical and anisotropic |
| 139 |
Horwitz, Chichilnisky, & Albright |
Luminance transients facilitate subsequent blue-yellow signals in individual macaque v1 neurons |
| 140 |
Solomon, Peirce, Krauskopf, & Lennie |
Chromatic sensitivity of surround suppression in macaque V1 and V2 |
| 141 |
Shevell & Monnier |
Induction from patterned S-cone backgrounds: Receptoral or postreceptoral basis? |
| 142 |
Teller, Civan, Bronson-Castain, & Pereverzeva |
Infants' spontaneous hue preferences are not due solely to variations in perceived brightness |
| Control of Eye Movements |
143 |
Stevenson, Mulligan, & Cormack |
Attention adds a long latency component in eye movement correlograms |
| 144 |
Liston, Chukoskie, & Krauzlis |
Max rules: modeling the where and when of saccadic decisions |
| 145 |
Vishwanath & Kowler |
Saccadic localization is affected by cues to 3D shape |
| 146 |
Sommer & Wurtz |
The frontal eye field sends predictively remapped visual signals to the superior colliculus |
| 147 |
Connolly, Goodale, Goltz, & Munoz |
FMRI activation related to preparatory set is correlated with saccade latency in human frontal eye fields but not in the supplementary motor area |
| 148 |
DeAngelis, Wei, & Angelaki |
Does the oculomotor system make use of high-level visual cues to viewing distance? |
| Visual Cortical Coding |
149 |
Braddick, O'Brien, Rees, Wattam-Bell, Atkinson, & Turner |
Linear and non-linear responses to form coherence in extra-striate cortical areas |
| 150 |
Smith, Williams, & Singh |
Sensitivity to direction of gaze in human posterior parietal cortex |
| 151 |
Movshon, Smith, & Kohn |
Responses to glass patterns in macaque V1 and V2 |
| 152 |
Samonds, Allison, Brown, & Bonds |
Cooperative synchronized assemblies and orientation discrimination |
| 153 |
Vanni, Dojat, Warnking, Segebarth, & Bullier |
Global interaction appears first in the temporo-occipital cortex |
| 154 |
Sheinberg |
The most reliable period for temporal cortical neurons |
| Attention 1 |
155 |
Hochstein & Shneor |
It may be easier to see two things at the same time! |
| 156 |
Scholl, Noles, Pasheva, & Sussman |
Talking on a cellular telephone dramatically increases 'sustained inattentional blindness' |
| 157 |
Strayer, Drews, & Johnston |
Inattention-blindness behind the wheel |
| 158 |
Dickinson, Chen, & Zelinsky |
Explicitly marking rejected distractors in an overt visual search task |
| 159 |
Carrasco, Giordano, & McElree |
Can covert attention eliminate temporal disparities in the visual field? |
| 160 |
van Ee, van Dam, Brouwer, & Korsten |
Bistable stereoscopic 3D percepts: Will-power, flip frequency, eye movements and blinks |
| Learning and Plasticity 1 |
161 |
Yu, Klein, & Levi |
Perceptual learning of contrast discrimination |
| 162 |
Gold |
Dynamic classification images reveal the effects of perceptual learning in a hyperacuity task |
| 163 |
Fiser & Aslin |
Element predictability not high occurrence frequency determines feature learning from multi-element scenes |
| 164 |
Bavelier & Green |
When video game playing expands your mind's eye |
| 165 |
Eckstein, Pham, & Shimozaki |
The efficiency of the use of feedback in perceptual learning |
| 166 |
Tanaka, Miyauchi, Imaruoka, Misaki, Matsumoto, & Tashiro |
Transfer of long-range interaction across the visual hemifield by reversed visual input |
| Motion 1 |
167 |
Tse |
fMRI reveals the neuronal substrate underlying form and motion processing in transformational apparent motion |
| 168 |
Yeshurun & Levy |
Apparent motion is less apparent with attention |
| 169 |
Carlson, Schrater, & He |
Second order motion is not second-class: A new illusion in Motion Perception |
| 170 |
Anstis |
The cogwheel illusion |
| 171 |
Verstraten, Kanai, Paffen, & Gerbino |
What makes local dots turn into moving global surfaces? |
| 172 |
Melcher & Morrone |
Spatiotopic temporal integration of motion across saccades |
| Learning and Plasticity 2 |
173 |
Sagi, Adini, Tsodyks, & Wilkonsky |
Context dependent learning in contrast discrimination: effects of contrast uncertainty |
| 174 |
Vidnyánszky & Sohn |
Attentional learning: learning to bias sensory competition |
| 175 |
Backus |
Optimal learning rates for unbiased perception |
| 176 |
Chun, Yi, Kelley, & Marois |
Attentional modulation of scene learning in the parahippocampal place area and of face learning in the fusiform face area |
| 177 |
Seitz & Watanabe |
How can subliminal perceptual learning be active? |
| 178 |
Mednick, Nakayama, & Stickgold |
Perceptual learning after a nap: The Mini-Me of Sleep |
| Attention/Switching |
179 |
Silver, Ress, & Heeger |
Sustained attention-related activity in primary visual cortex |
| 180 |
Lesmes, Lu, Dosher, & Sperling |
Comparing the temporal dynamics of intra- and cross-modal attention switching. |
| 181 |
Horowitz, Birnkrant, & Wolfe |
Rapid visual search during slow attentional shifts |
| 182 |
Chen, Eckstein, & Shimozaki |
The temporal dynamics of attention in a spatial cueing task revealed by classification movies |
| 183 |
Hafed & Clark |
Detecting patterns of covert attention shifts in psychophysical tasks using microsaccades |
| 184 |
Murray, Sekuler, & Bennett |
A linear cue combination framework for understanding selective attention |
| Temporal Factors |
185 |
Holcombe |
Perceptual binding of letters into words is low temporal resolution |
| 186 |
Harris, Kopinska, & Duke |
Flash lag in depth |
| 187 |
Tadin, Lappin, & Blake |
High temporal precision for perceiving event offsets |
| 188 |
Shim & Cavanagh |
Attentive tracking can modulate the illusory misalignment of a flash |
| 189 |
Eagleman & Sejnowski |
Motion-biasing, not asynchronous feature binding, explains the feature-flash drag effect |
| 190 |
Arnold, Clifford, & Johnston |
Distorting time with motion |
| Object Recognition |
191 |
Kourtzi, Tolias, Altmann, Augath, & Logothetis |
Integration of local features into global shapes: monkey and human fMRI studies |
| 192 |
Zago & Bar |
THE RISE AND FALL OF VISUAL PRIMING |
| 193 |
O'Toole, Haxby, & Abdi |
Classification-based approaches to the analysis of functional neuroimaging data on face and object perception |
| 194 |
Wang, Yen, & Wang |
Reading word “airplane” is seeing object “airplane” in the right cerebral hemisphere: The effect of object contour diagnosticity on within-modal and cross-modal priming |
| 195 |
Zhu & von der Malsburg |
Object recognition by Dynamic Link Matching in biologically realistic time |
| 196 |
Torralba, Oliva, & Freeman |
Object recognition by scene alignment |
| 197 |
James & Gauthier |
fMRI studies of multi-modal semantic knowledge using artificial concepts |
| Motion 2 |
198 |
Purushothaman & Bradley |
Single neuron sensitivity for a fine motion discrimination task |
| 199 |
Liu & Newsome |
Correlation between MT activity and behavioral judgment of visual speed in macaque monkeys |
| 200 |
Krekelberg, Dobkins, & Albright |
Fourier motion energy analysis in macaque MT |
| 201 |
Bair & Movshon |
A neural substrate for illusory motion induced by static orientation: responses of complex direction selective neurons in macaque V1 |
| 202 |
Ruppertsberg, Wuerger, & Bertamini |
S-cone input into global motion processing |
| 203 |
Dobkins, Fine, Hsueh, & Vitten |
Infants integrate local motion |
| 204 |
Kiorpes & Movshon |
Differential development of form and motion perception in monkeys |
| Texture |
205 |
Sezikeye & Gurnsey |
Texture regions are more easily detected than texture edges |
| 206 |
Prins & Kingdom |
The first conclusive evidence for the existence of energy-based texture mechanisms |
| 207 |
Dang, Tjan, & Chung |
Spatial phase related nonlinearity in alignment of contours |
| 208 |
Zhaoping & Snowden |
A psychophysical test of the saliency map in V1 |
| 209 |
Victor, Conte, & Chubb |
Interaction of first-order and isodipole statistics in a texture segregation task |
| Motion: Temporal Factors |
210 |
Bedell, Ramamurthy, Patel, & Vu-Yu |
The temporal impulse response function during smooth pursuit |
| 211 |
Cantor & Schor |
Velocity dependence of the Flash Lag Effect for narrowband stimuli - is it linear? |
| 212 |
Chappell, Hardwick, & Hine |
Combining the Poggendorff and flash-lag illusions |
| 213 |
Kelly, Beall, & Loomis |
Postural control without optic flow |
| 214 |
Cohn, Nguyen, & Barton |
A visual factor in rear-end collisions? |
| Spatial Vision: Orientation, Clinical |
215 |
Mareschal & Shapley |
The effects of contrast and size on orientation discrimination |
| 216 |
Sally & Gurnsey |
Orientation discrimination across the visual field: size scaling estimates at near threshold levels of contrast |
| 217 |
Mullen & Beaudot |
Global or local shape discrimination of radial frequency patterns? |
| 218 |
Betts, Bennett, & Sekuler |
Age-related changes in orientation discrimination: Calculation efficiency or equivalent input noise? |
| 219 |
Trevethan & Sahraie |
Factors affecting stimulus detection in the cortically blind |
| 220 |
Hoffmann, Straube, & Bach |
Boosting multifocal VEP responses from the central visual field with pattern onset stimulation |
| Space Perception |
221 |
Bonneh & Cooperman |
Motion induced blindness is affected by head-centered and object-centered mechanisms |
| 222 |
Dagnelie, Yin, Hess, & Yang |
Phosphene mapping strategies for cortical visual prosthesis recipients |
| 223 |
Girshick, Vishwanath, & Banks |
Surface cues and the perception of pictures |
| 224 |
Johnston, Durant, & Dale |
A labile representation of spatial information in the visual cortex |
| 225 |
Matin & Li |
Gaze direction and extraretinal eye position information; Retinal orientation and eccentricity of a 1-line inducer: Separate and combined influences on visually perceived eye level (VPEL) |
| 226 |
Nishimura & Yokosawa |
Orthogonal S-R compatibility and stimulus saliency |
| 227 |
Riener, Stefanucci, Proffitt, & Clore |
An effect of mood on perceiving spatial layout |
| Search |
228 |
Simoni & Motter |
Human Search Performance is a Threshold Function of Cortical Image Separation |
| 229 |
Roggeveen, Kingstone, & Enns |
Symmetry relations influence target-distractor comparison in visual search |
| 230 |
Kenner & Wolfe |
An exact picture of your target guides visual search better than any other representation |
| 231 |
Smilek, Dixon, & Merikle |
The influence of meaning and search strategy on the efficiency of visual search |
| 232 |
Peterson & Rauschenberger |
Context effects on border assignment in the target stimulus in visual search |
| 233 |
Porter, Troscianko, & Gilchrist |
Memory deployment in visual search: insights from pupillometry |
| Scene Perception |
234 |
Bacon, Vinette, Gosselin, & Faubert |
What primes in unconscious repetition priming |
| 235 |
Hollingworth |
Short- and long-term memory contributions to the online visual representation of natural scenes |
| 236 |
Intraub, Akers, Fiorito, & Simoshina |
Representation of occluded objects in natural scenes: Are all forms of occlusion equal? |
| 237 |
Davenport |
Rapid scene processing: Can a salient central object influence background perception? |
| 238 |
Chong & Treisman |
Parallel extraction of statistical descriptors in visual displays |
| 239 |
McCotter, Gosselin, Sowden, & Schyns |
The visual information underlying the categorization of natural scenes |
| Perceptual Organization |
240 |
Guttman, Sekuler, & Kellman |
Temporal variations in visual completion: A reflection of spatial limits? |
| 241 |
Puts & de Weert |
Temporal aspects of global form perception |
| 242 |
van der Vloed, Csatho, & van der Helm |
Robustness of bilateral symmetry to temporal offset |
| 243 |
Scholte, Jolij, Spekreijse, & Lamme |
Neural correlates of texture boundary detection and surface segregation are present in human V1 |
| 244 |
Scheessele & Perez |
Effect of region information on perception of partially occluded figures |
| 245 |
Xu, Shen, & Li |
Figure-ground segregation and spatial phase tuning of extra-receptive field of V1 neurons in awake monkey |
| 246 |
Hulleman, Gedamke, & Humphreys |
A new way of assessing the strength of a figure-ground cue |
| 247 |
Grossberg & Yazdanbakhsh |
Laminar cortical dynamics of 3-D surface stratification, transparency, and neon spreading |
| 248 |
Bravo & Farid |
Searching a cluttered scene |
| 249 |
Liu & Lu |
Object recognition impedes stereo discrimination |
| 250 |
Davies, Ozgen, Pilling, & Wiggett |
Categorical perception, perceptual magnet and prototype-bias: same or different phenomena? |
| 251 |
Palmer & Kellman |
(Mis)Perception of motion and form after occlusion: Anorthoscopic perception revisited |
| 252 |
Zhou & Mel |
Combining Multiple Cues for Contour Detection: Lessons from (and to) the Visual Cortex |
| 253 |
Rauschenberger, Liu, Slotnick, & Yantis |
Cortical representation of pictorial occlusions in early visual areas and LOC |
| 254 |
Chen & He |
What factors determine the stabilization of a bi-stable stimulus? |
| Perceptual Learning |
255 |
Gee & Merigan |
Generalization of perceptual learning across the visual field |
| 256 |
Hussain, Bennett, & Sekuler |
How much practice is needed to produce perceptual learning? |
| 257 |
Notman & Sowden |
Learned categorical perception is spatial frequency specific: an effect of categorisation on early visual processing |
| 258 |
Pavlovskaya & Hochstein |
Hemispheric specificity of perceptual learning effects under hard conditions |
| 259 |
Rosenthal & Behrmann |
Acquiring long term visual representations in visual form agnosia |
| 260 |
Saffell & Matthews |
Perceptual learning reveals separate neural events for speed and direction |
| Perception and Action |
261 |
Schlicht & Schrater |
Bayesian model for reaching and grasping peripheral and occluded targets |
| 262 |
Wilson, Bingham, & Collins |
Contribution of Visual vs. Haptic Perception to the Stability of Relative Phase in Coordinated Movement |
| 263 |
Cant, Westwood, Valyear, & Goodale |
No evidence for visuomotor priming in a visually-guided action task |
| 264 |
Song & Nakayama |
The role of focal visual attention in a manual pointing task |
| 265 |
Hadjigeorgieva, Friedrich, & Pollick |
Perception and action in drawing circles |
| Object Recognition |
266 |
Huberle, Deubelius, Lutzenberger, Bülthoff, & Kourtzi |
Temporal properties of shape processing across visual areas: a combined fMRI and MEG study |
| 267 |
Pelli, Martelli, Majaj, & Berger |
One channel per object? |
| 268 |
Lomber & Kopacz |
Learning and recall of object and pattern discriminations during bilateral reversible deactivation of the superior colliculus |
| 269 |
Bennett |
A stereo advantage in generalizing over rotations in depth on a same-different successive matching task |
| 270 |
Cohen, Barenholtz, Singh, & Feldman |
Superior change detection at shape concavities |
| 271 |
Nagai & Yokosawa |
Superordinate interference in basic level object recognition: The effects of object typicality |
| Motion 1: Integration & Disorders |
272 |
Lappin, Tadin, & Panduranga |
Center-surround antagonism affects visual motion coherence |
| 273 |
Nishida |
Perception of coherent pattern in motion |
| 274 |
Hoag, Chapman, & Giaschi |
Motion coherence thresholds can be elevated by flicker adaptation or red background |
| 275 |
Bowns & Alais |
Catastrophic Switching of Perceived Motion Direction |
| 276 |
Di Luca, Domini, & Caudek |
Spatial integration of curved surfaces in structure from motion |
| 277 |
Benton & Curran |
Direction repulsion - a local or global phenomenon? |
| 278 |
Nichols, Hock, Ploeger, & Schöner |
Linking levels in motion pattern formation through dynamical coupling: evidence from psychophysics and simulations |
| 279 |
Barraza & Grzywacz |
Parametric decomposition of complex motion by humans |
| 280 |
Koyama, Sasaki, Tootell, & Watanabe |
The neural correlates of global flow motion by fmri in the conditions in which motion opponency and attention were controlled |
| 281 |
Wada, von Grünau, Lacroix, de Almeida, Gurnsey, & Segalowitz |
The effect of dot lifetime, dot size, & percent area covered by dots on motion coherence thresholds: Implications for diagnosing reading difficulties |
| 282 |
Schluppeck & Engel |
Oblique effect in human MT+ follows pattern rather than component motion |
| 283 |
Mather & Daniell |
Direction discrimination performance measured using a Fourier domain signal-to-noise paradigm |
| 284 |
Cobo-Lewis & Hetley |
Bias past the vector-sum direction in Type 2 plaids |
| 285 |
Anderson, Fine, & Dobkins |
Contrast, coherence and directional tuning |
| 286 |
Blaser, Papathomas, & Vidnyanszky |
Polarity-contingent motion aftereffects at the stage of local motion processing |
| 287 |
Atkinson, Braddick, Anker, Nardini, Bellugi, Rose, Searcy, & Bavar |
Extending the ‘dorsal stream vulnerability hypothesis’: Spatial reorientation and motion and form coherence in children and adults with Williams syndrome |
| 288 |
Reiss, Hoffman, & Landau |
Motion processing in Williams syndrome: Evidence against a general dorsal stream deficit |
| 289 |
MacKay, Jakobson, Ellemberg, Lewis, Mauer, & Casiro |
Deficits in the processing of local and global motion in very low birthweight children |
| 290 |
Christman, Setterberg, & Nawrot |
Motion perception with 5-HT2 receptor-blocking medications |
| Lightness/Shading |
291 |
Singh |
Lightness constancy through transparency |
| 292 |
Troncoso, Macknik, & Martinez-Conde |
Low-level mechanisms for processing of junctions |
| 293 |
Khang, Koenderink, & Kappers |
Perception of the direction of illumination in shaded images of convex polyhedra |
| 294 |
Clifford & Spehar |
Using colour to disambiguate contrast and assimilation in White's Effect |
| 295 |
Ripamonti, Bloj, Hauck, Mitha, & Brainard |
Object lightness constancy: effects of object pose and shape |
| Face Perception |
296 |
Kaping, Mizokami, & Webster |
Adapting to a new visual environment: A field study of face perception |
| 297 |
Simas & Santos |
The multiple-faces effect: occurrence and frequency using digitized achromatic photos |
| 298 |
Rhodes, Jeffery, Watson, Clifford, & Nakayama |
Face attractiveness aftereffects: fitting the mind to the world |
| 299 |
Russell |
Contrast, sex, and facial attractiveness |
| 300 |
Goren & Wilson |
Quantifying recognition abilities for four major emotional expressions based on facial geometry |
| 301 |
Gosselin, Adolphs, & Schyns |
Recognition of emotion in facial expressions with and without the amygdala |
| 302 |
Heard |
A hollow face does not express emotion |
| 303 |
Roark, O'Toole, & Abdi |
Recognizing people from naturalistic video: The effects of facial motion and familiarity |
| 304 |
Knappmeyer, Giese, & Bülthoff |
Spatio-temporal caricature effects for facial motion |
| 305 |
Lee, Wilson, & Rivest |
Matching faces in a prosopagnosic individual |
| Eye Movement Cognitive |
306 |
Simion & Shimojo |
Gaze Manipulation Biases Preference Decisions |
| 307 |
Wieth, Castelhano, & Henderson |
I See What You See: Gaze Perception during Scene Viewing |
| 308 |
de Almeida, van de Velde, von Grunau, & Galera |
(Eye-)Tracking the time-course of the interaction between linguistic and visual processes: the effect of verb-conceptual restrictions |
| 309 |
Yu & Ballard |
A formal model of visual attention in embodied language acquisition |
| 310 |
Pelz, Canosa, Lipps, Babcock, & Rao |
Saccadic targeting in the real world |
| 311 |
Duchowski, Marmitt, Desai, Gramopadhye, & Greenstein |
Algorithm for comparison of 3D scanpaths in virtual reality |
| Color |
312 |
Heckman & Engel |
Spatial frequency modulates color selectivity of adaptation to contrast patterns |
| 313 |
Shapiro & D'Antona |
Independent directions in color space delineated by contrast-induced phase lags |
| 314 |
Long & Purves |
Evidence that color contrast effects have a probabilistic foundation |
| 315 |
Parraga, Troscianko, Troscianko, Tolhurst, & Leonards |
Spatiochromatic properties of images of fruits and leaves from Kibale forest, Uganda |
| 316 |
Amano & Foster |
Color constancy under illuminant and context changes |
| Binocular Vision: Stereo |
317 |
Goutcher & Mamassian |
Selective biasing of correspondence matching in ambiguous stereograms |
| 318 |
Lankheet & Beltman |
Horizontal and vertical noise tolerance of binocular correlation in random dot stereograms |
| 319 |
Zhang, Ghose, & Schor |
Temporal limit of the smoothness constraint for binocular matching |
| 320 |
Berends & Schor |
Stereo-slant adaptation involves both disparity coding and perceived slant |
| Binocular Vision: Rivalry |
321 |
Paffen, Kanai, te Pas, & Verstraten |
Binocular rivalry between moving stimuli: The effect of surround motion |
| Attention 1 |
322 |
Hyun, Woodman, Vogel, Niese, & Luck |
How are visual inputs compared with memory representations in the change-detection paradigm? |
| 323 |
Bullot, Droulez, & Pylyshyn |
Keeping track of objects while exploring an informationally impoverished environment: Local deictic versus global spatial strategies |
| 324 |
Noles & Scholl |
The persistence of object-file representations |
| 325 |
Fenske, Kessler, Raymond, & Tipper |
Attentional inhibition determines emotional responses to unfamiliar faces |
| 326 |
Fecteau & Munoz |
Sensory signals predict performance on a non-predictive cue-target task |
| 327 |
Clarke & Paradiso |
A performance deficit at the site of attentional cueing |
| 328 |
Lanagan & Moore |
Contrasting the resolution of exogenously and endogenously controlled attention |
| 329 |
Read, Ling, & Carrasco |
Covert attention alters visual appearance |
| 330 |
Liu, Austen, Rempel, Booth, Fisher, & Enns |
Multiple object tracking is scene-based, not image-based |
| 331 |
Li, VanRullen, Koch, & Perona |
Natural scene categorization in the near absence of attention: further explorations |
| 332 |
Reddy, VanRullen, & Koch |
Inter-stimulus distance effects in visual search |
| 333 |
Olds & Degani |
Change detection and heterogeneity |
| 334 |
Amso & Scott |
Using eye movements as a measure of selective attention: Evidence from a spatial negative priming paradigm |
| 335 |
Skow-Grant & Peterson |
Where has object-based IOR gone? |
| 336 |
Hoffman & Burton |
Do different systems mediate attention to space vs. objects?: |
| 337 |
DiMase, Alvarez, Horowitz, & Wolfe |
Constraints on task switching in multielement tracking and visual search |
| 338 |
Mitroff, Scholl, & Wynn |
The relationship between object files and conscious perception |
| 339 |
Ogawa & Yagi |
Priming effects in multiple object tracking: An implicit encoding based on global spatiotemporal information |
| 340 |
Tripathy |
Severe loss of positional information when tracking multiple dots |
| Spatial Vision: Context, Contrast, Detection & Models |
341 |
MacLeod & Beer |
The extended Maxwellian view |
| 342 |
Polat, Bonneh, & Sagi |
Lateral interactions and crowding in amblyopia |
| 343 |
Bradley, Barrett, Pacey, Thibos, & Morrill |
Non-veridical perception in human amblyopia: perceptual evidence of neural changes in visual cortex |
| 344 |
Sowden, Ozgen, & Schyns |
Tuning of expectancy effects indicates top-down attentional modulation of SF channels |
| 345 |
Varadharajan & Foley |
Effects of flanking patterns on contrast detection and contrast discrimination |
| 346 |
Mancini, Gurnsey, & Sally |
Effects of grey scale range on the detection of symmetry and anti-symmetry |
| 347 |
Sukumar & Waugh |
Spatial extent and eccentricity effects for detection of luminance-defined and contrast-defined blob stimuli |
| 348 |
Laurinen, Olzak, & Saarela |
Complex contextual effects on apparent contrast |
| 349 |
Shimozaki, Eckstein, & Abbey |
Evidence from classification images of local and nonlocal induction effects upon contrast detection |
| 350 |
Billock & Tsou |
A special case of the MacKay effect generates geometric hallucinations: Stochastic resonance in pattern formation driven by fractal (1/f) noise |
| 351 |
Tani, Maruya, & Sato |
Reversed Cafe wall illusion |
| 352 |
Johnston & Timney |
Ethanol-induced changes in Westheimer functions consistent with decreases in lateral inhibition |
| 353 |
Li, Levi, & Klein |
Spatial noise provides new insights into the “receptive field” for Vernier acuity |
| 354 |
Habak, Wilkinson, Zakher, & Wilson |
Contextual effects in form perception |
| 355 |
Peterson & McIlhagga |
In search of the early nonlinearity: no luck yet |
| 356 |
Barlow, Khan, & Farell |
Time of day and glucose modulate visual sensitivity |
| 357 |
Chirimuuta & Tolhurst |
Can a 'dipper' function model of primary visual cortex predict pattern discrimination processing? |
| 358 |
Nadell, Zenger-Landolt, & Heeger |
Linking visual masking effects with fMRI responses in early visual areas |
| 359 |
Gurnsey & Poirier |
Non-monotonic eccentricity effects explained by multiple scaling theory |
| 360 |
Georgeson, May, & Barbieri-Hesse |
Perceiving edge blur: the Gaussian-derivative template model |
| 361 |
McIlhagga |
Are human observers performing wavelet denoising? |
| Receptive Fields |
362 |
Kozyrev & Kremers |
Modelling foveal ganglion cell arrays in primates |
| 363 |
Cheung, He, Carlson, Legge, & Hu |
Estimating retinal fixation location using fMRI |
| 364 |
Rucci & Casile |
Decorrelation of neuronal responses during eye movements: possible implications for the refinement of V1 receptive fields |
| 365 |
Parsons & Rucci |
A model of the possible influences of eye movements on the maturation of cortical direction selectivity |
| 366 |
Royal, Sáry, Schall, & Casagrande |
Is there a relationship between spike bursts in the lateral geniculate nucleus (LGN) and behavioral events? |
| 367 |
Kagan, Przybyszewski, Gur, & Snodderly |
Responses of macaque V1 neurons to fixational and voluntary eye movements correlate with receptive field properties |
| 368 |
Kremers & Kozyrev |
The influence of spatial displacement between stimulus and receptive field upon the responses of LGN cells |
| 369 |
Van Hooser, Heimel, Chung, & Nelson |
Receptive field properties and laminar organization in the lateral geniculate nucleus of the gray squirrel (sciurus carolinensis) |
| 370 |
Schummers & Sur |
Orientation selective responses to the offset of grating stimuli |
| 371 |
Bi, Zhang, Zheng, Maruko, Sakai, Smith, & Chino |
The effects of short periods of strabismus on cortical binocularity |
| 372 |
Maruko, Bi, Zhang, Zheng, Sakai, Smith, & Chino |
Comparisons of interocular suppression in v1 neurons of normal neonatal and infant strabismic monkeys |
| 373 |
Brown, Allison, Samonds, Thomas, & Bonds |
Characterization of Area 18 modulation from stimulation outside the receptive field of Area 17 cells in the cat |
| 374 |
Bridge, Clare, Jezzard, Parker, & Matthews |
A comparison of structurally and functionally defined human primary visual cortex |
| 375 |
McLoughlin & Schiessl |
The organisation of space and orientation preference in V1 of the marmoset monkey |
| 376 |
Emeric, Xu, Mavity-Hudson, Gallucci, Thomas, Barahimi, Shima, Stefansic, & Bonds |
Visuotopic organization of bush baby primary visual cortex (V1) revealed by optical imaging |
| 377 |
Knight & Victor |
Functions confined in space and spatial frequency include Gabor-like functions as well as intrinsically two-dimensional functions resembling "non-Cartesian" gratings |
| 378 |
Siege, Duann, Jung, & Sejnowski |
Independent component analysis and the functional architecture of the inferior parietal cortex of behaving monkey |
| 379 |
Thomas, Gallucci, Xu, Allison, Stefansic, Shima, Casagrande, & Bonds |
Compound stimuli promote architectural reorganization in cat striate cortex |
| Perception and Action |
380 |
Tresilian |
A simple empirical law for a class of visually timed interceptive actions |
| 381 |
Fox, Lintal, Modesto, & Owens |
Sensory input for real-world, controlled braking |
| 382 |
Li, Matin, & Semanek |
Accuracy in manually matching the height of a perceptually mislocalized visual target increases with hand-body distance as does manual pointing |
| 383 |
Stockmeier, Horton, & Franz |
How do we grasp (virtual) objects in three-dimensional space? |
| 384 |
Steeves, Levine, Humphrey, & Goodale |
Response modality does not affect detection latency in a contrast sensitivity task |
| 385 |
Post & Welch |
Studies of open loop pointing with induced motion |
| 386 |
Maloney, Trommershauser, & Landy |
MEGaMove: A maximum expected gain model of movement under risk |
| 387 |
Cuijpers, Brenner, & Smeets |
Distorted shape perception impairs grasping of real objects |
| 388 |
Mon-Williams, Murphy, & Hibbard |
The tactics and timing of smooth corrections in human arm movements |
| 389 |
Lopez-Moliner, Smeets, & Brenner |
Perceptual judgements and manual tracking are equally affected by an expansion/contraction illusion |
| 390 |
Brenner & Smeets |
Slow corrections to arm movements for target perturbations in depth |
| 391 |
Khan, Rossetti, & Crawford |
Eye-centered remapping in patients with bilateral parietal lobe lesions |
| 392 |
McConnell, Vallee, Munevar, & Lee |
Thresholds for detecting a difference between seen and felt position of the hand |
| Motion 2: Speed, Heading, Physiology |
393 |
Ogmen, Camuz, Patel, & Bedell |
Transient and steady-state phases of position computation for a moving target |
| 394 |
Khurana, Watanabe, & Nijhawan |
Flash lag Effect: Speeding up to get ahead? |
| 395 |
Disch, De Valois, & Takeuchi |
Speed perception of flickering stimuli |
| 396 |
Watamaniuk |
The perceived speed of global flow |
| 397 |
Tavassoli, Palmer, & Cormack |
Frequency and space domain classification images for motion detection |
| 398 |
Curran & Benton |
The role of apparent contrast in the speed tuning of direction repulsion |
| 399 |
Wurfel, Grzywacz, & Barraza |
Measurement of rate of expansion in the perception of radial motion |
| 400 |
Thompson |
Reducing contrast really can speed up faster-moving stimuli |
| 401 |
Harrison, Rensink, & van de Panne |
Detecting changes of velocity of smoothly moving objects |
| 402 |
Amano & Takeda |
Correlation between magnetoencephalogram (MEG) evoked by changes in motion velocity and reaction times or discrimination thresholds |
| 403 |
Dyre, McDevitt, Schaudt, & Triplett |
Motion parallax affects perceived global speed |
| 404 |
Anderson, Nover, & DeAngelis |
Modeling the velocity tuning of macaque MT neurons |
| 405 |
Curnow, Krug, & Parker |
Similar temporal specificity of perceptual choice signals across a large pool of V5/MT neurons |
| 406 |
Chelvanayagam, Zaksas, & Pasternak |
Activity in MT neurons is affected by the nature of motion discrimination required by the working memory task |
| 407 |
Christopher, Livingstone, Duffy, & Born |
Two-dimensional motion signals in primary visual cortex of alert macaques |
| 408 |
Nelissen, Vanduffel, Tootell, van Beerendonk, & Orban |
The effect of stimulus size, speed and eccentricity on the motion responses in macaque visual areas. A combined fMRI and double label deoxyglucose (2-DG) study. |
| 409 |
Ibbotson, Price, & Clifford |
Acceleration sensitivity and habituation in PMLS neurons |
| 410 |
Rizzo, Lamers, Skaar, Sauer, Ramaekers, & Andersen |
Perception of heading in abstinent MDMA and THC users |
| 411 |
Schulte-Pelkum, Riecke, von der Heyde, & Bülthoff |
Screen curvature does influence the perception of visually simulated ego-rotations |
| 412 |
Senoo & Sato |
The contribution of higher-order motion on vection and body sway |
| 413 |
Roth, Domini, & Black |
Specular Flow and the Perception of Surface Reflectance |
| Lightness/Shading |
414 |
Tarr & Kersten |
Estimating lighting models in a scene through lightness judgments |
| 415 |
Hong & Grossberg |
Cortical dynamics of surface lightness anchoring, filling-In, and perception |
| 416 |
Agostini & Castellarin |
Interaction of chromatic and achromatic surfaces in lightness perception |
| 417 |
Logvinenko |
Is luminance contrast necessary to perceive lightness? |
| 418 |
Soranzo & Agostini |
Perceptual grouping in illumination-independent lightness constancy |
| 419 |
Freeman & Torralba |
Shape recipes: scene representations that refer to the image |
| 420 |
Zavagno, Annan, & Liu |
The Five-Square Gelb Illusion Revisited |
| 421 |
Zemach |
Spatial decay of achromatic color induction differs for lightness and darkness induction processes |
| 422 |
Blakeslee & McCourt |
The effect of spatial frequency on the White, shifted White and checkerboard iIllusions: Data and modeling |
| 423 |
Yang & Purves |
Statistical concatenations of luminance can explain lightness/brightness percepts |
| 424 |
McCourt & Foxe |
Brightening prospects for "early" cortical coding of perceived luminance |
| 425 |
Leonards, Ibanez, Zavagno, Seghier, & Troscianko |
A cortical region for luminosity perception - An fMRI study |
| 426 |
Snyder & Maloney |
Lightness Estimation in Three-Dimensional Scenes with and without Specular Cues |
| Eye Movement Mechanisms |
427 |
Dean & Platt |
Spatial representations in posterior cingulate cortex |
| 428 |
Simola & Kojo |
Eye movements during directed visual search: the effects of background versus target-distractor confusability |
| 429 |
Over, Hooge, & Erkelens |
Visual search: saccade parameters depend on the shape of the search area |
| 430 |
Porrill, Warren, & Dean |
The role of torsional viscosity in saccadic listing’s law |
| 431 |
Andre, Dunsmoor, & Waite |
The relationships among oculomotor resting states and computer monitor positioning |
| 432 |
Yang |
Curvature of Saccade Trajectory: The Dynamic Interaction of Anticipation-based and Stimulus-based Movement-related Activation |
| 433 |
Carello & Krauzlis |
Subthreshold microstimulation in the primate superior colliculus alters both the latency of saccades and target choice in a 2-AFC task |
| 434 |
Madelain & Krauzlis |
Pursuit of the ineffable: perceptual and motor reversals during the tracking of apparent motion |
| 435 |
Fujita |
A model for the adaptation of saccades by the cerebellum |
| 436 |
Fowler & Krauzlis |
Target-switching by pursuit and saccades guided by shifts of attention |
| 437 |
Wiewiora, Berg, Triesch, & Hashiyama |
Learning Optimal Gaze Decomposition |
| 438 |
Mulligan & Stevenson |
The contrast dependence of eye-movement latencies |
| 439 |
Palmer, Lien, Rajashekar, & Cormack |
Abrupt visual onsets elicit involuntary reflexive eye movements |
| Eye Movement Cognitive |
440 |
Theeuwes & Godijn |
Attentional and oculomotor inhibition |
| Eye Movement Mechanisms |
441 |
Adler & Krauzlis |
Effects of prior sensory and motor information on the intitiation of pursuit and saccades |
| Color |
442 |
Page & Crognale |
Behavioral and electrophysiological measures of aging in visual pathways |
| 443 |
Fry, Highsmith, & Crognale |
A study of the phenotypic differences manifested in blue-cone monochromacy |
| 444 |
Mizokami, Webster, & Webster |
Seasonal variations in the color statistics of natural images |
| 445 |
Smith & Pokorny |
Interactions of chromaticity and luminance in edge identification depend on chromaticity |
| 446 |
Schirillo, Heckman, & Barra |
A chromatic test of shadow compatibility and equal cone excitation ratios |
| 447 |
Kuriki |
Nonlinear adjustment of visual sensitivity balance in a real world |
| 448 |
Yang & Mulligan |
Readability of chromatic transparent text on a patterned background |
| 449 |
Wang, Richters, & Eskew |
Interactions of S cone increments and decrements with L and M cone signals |
| 450 |
Doerschner, Boyaci, & Maloney |
Human observers compensate for secondary illumination originating in nearby chromatic surfaces in making achromatic settings |
| 451 |
Boyaci, Doerschner, & Maloney |
Achromatic settings in three-dimensional scenes with two light sources differing in chromaticity |
| Binocular Vision: Rivalry |
452 |
Ooi & He |
On the initiation and spreading of interocular suppression from binocular vertical contours |
| Binocular Vision: Computational |
453 |
Read & Cumming |
Modeling the cortical specialization for horizontal stereoscopic disparities |
| Binocular Vision: Matching |
454 |
Li & Farell |
Coarse-to-fine or fine-to-coarse? |
| 455 |
Häkkinen |
Interocular transformational apparent movement in HMD misalignment detection |
| Binocular Vision: Depth |
456 |
Mansouri, Hess, Allen, Sebbag, & Dakin |
The site of orientation integration |
| 457 |
Duke & Howard |
Vertical disparity pooling in 3D |
| 458 |
Fukuda, Matsumiya, & Kaneko |
Temporal Pooling of Vertical Size Disparity for Slant Perception |
| Binocular Vision: Stereo |
459 |
Lee, Shioiri, & Yaguchi |
Different temporal frequency tunings in different spatial frequency stimuli for depth perception |
| Binocular Vision: Depth |
460 |
Stelmach & Buckthought |
Pedestal depth discrimination for contrast modulated noise |
| 461 |
Matza-Brown & Backus |
Evidence for combination of two methods for measuring relative disparity |
| 462 |
Farell |
Relative binocular disparity: relative to what? |
| 463 |
Howard & Duke |
Depth from monocular images |
| 464 |
Gheorghiu & Erkelens |
Depth from rapidly alternating disparities |
| 465 |
Patel & Bedell |
Perceived depth from veridical and aliased binocular phase disparities in a random-dot (RD) stimulus |
| 466 |
Gepshtein, Banks, & Landy |
Spatial resolution of stereopsis |
| 467 |
van Dam & van Ee |
Bistability in stereoscopically perceived slant about a horizontal axis |
| 468 |
Fernandez & Farell |
Diminished discriminability of motion in depth after adaptation to frontoparallel motion |
| Attention 2 |
469 |
Fanini, Luana, Giuseppe, Mirabella, & Chelazzi |
Spatial and non-spatial attention effects in the activity of macaque posterior parietal cortex neurons |
| 470 |
Barnes, Malhotra, Payne, & Lomber |
Regions of extrastriate cortex mediating visual neglect: reversible deactivation of 15 loci in the cat |
| 471 |
Woller, Tesla, Payne, & Lomber |
Cortico-collicular interactions mediating visual attention |
| 472 |
McKeeff, Remus, & Tong |
Bottlenecks in cortical processing of objects: a category specific phenomenon |
| 473 |
Vaucher, Quirion, & Laplante |
Pattern visual stimulation elicits cortical acetylcholine release with regional specificity in the anesthetized rat |
| 474 |
Ben-Shahar, Scholl, & Zucker |
Where objects come from: Attention, segmentation, and textons |
| 475 |
Bendiksby & Platt |
Effects of attention and motivation on neuronal activity in parietal cortex |
| Surfaces |
476 |
Albert |
Two influences of parallelism on the perception of illusory contours |
| 477 |
Stanley, Krishnan, & Rubin |
Real surfaces, illusory surfaces, and other perceptually completed regions: direct comparison of boundary sharpness |
| 478 |
Liu & Todd |
Effects of illumination direction on the perception of shape from shading for photometrically accurate images of randomly shaped surfaces |
| 479 |
Takeuchi & Matsuoka |
Spatiotemporal characteristics of illumination on surface material perception |
| 480 |
McDermott & Adelson |
Genericity and junctions in motion interpretation |
| 481 |
Nagasaka, Hori, & Osada |
Perception of transparency and amodal completion in pigeons |
| 482 |
Norman, Norman, Todd, Clayton, & McBride |
The perception and discrimination of local curvature on complex 3-D surfaces |
| 483 |
Kanai, Wu, & Shimojo |
Color-spreading selective for visual surfaces in transparent motion |
| Space Perception |
484 |
Awater & Lappe |
Compression of visual space under steady fixation |
| 485 |
Cai |
The Fröhlich effect is not due to a failure to perceive the beginning portion of motion trajectory |
| 486 |
Chan, Campos, & Sun |
Spatial representations obtained through map learning and through navigation in real and virtual environments |
| 487 |
Dassonville, Walter, & Bala |
Time course of apparent midline distortions during stroboscopic induced motion |
| 488 |
Gilson, Fitzgibbon, & Glennerster |
Dynamic performance of a tracking system used for virtual reality displays |
| 489 |
Giudice, Legge, & Bakdash |
Navigating without vision: A role for spatial language? |
| 490 |
Glennerster, Gilson, Tcheang, & Parker |
Perception of size in a `dynamic Ames room' |
| 491 |
Granrud, Granrud, Koc, Peterson, & Wright |
Perceived size of traffic lights: A failure of size constancy for objects viewed at a distance |
| 492 |
Jaekl, Jenkin, Dyde, & Harris |
Perceptual stability during active and passive head translation: variations with direction |
| 493 |
Morse & Rieser |
Linear vection shows a retinal frame of reference |
| 494 |
Poljac & Van den Berg |
Perception of the Plane of Regard |
| 495 |
Ribeiro-Filho, Matsushima, & Da Silva |
Angular declination as an exocentric distance cue: some hints for dissociation between perception and action systems |
| 496 |
Sedgwick, Gillam, & Leath |
Modeling perceived direction of slant in the presence of surface texture anisotropy |
| 497 |
Tcheang, Glennerster, Gilson, & Parker |
Systematic distortions of perceptual stability investigated using virtual reality |
| 498 |
Thompson, Ellard, & Moule |
Landmark navigation in a virtual environment: Integrative contributions from global and local landmarks |
| 499 |
Wu, He, & Ooi |
Vertical and horizontal references determined by linear perspective and optic flow information |
| 500 |
Wu, He, & Ooi |
Evidence for a sequential surface integration process hypothesis from judging egocentric distance with restricted view of the ground |
| Object Recognition |
501 |
Ho, Mahon, & Carrasco |
Developmental course of performance fields with familiar stimuli |
| 502 |
Kornmeier & Bach |
A new “Necker Cube” EEG paradigm reveals low level mechanisms in perceptual disambiguation |
| 503 |
Walker & Malik |
Can convexity explain how humans segment objects into parts? |
| 504 |
Fournier, Dyre, Patterson, Winters, & Wiediger |
Conjunction Benefits with First- and Second-order Features |
| 505 |
Martelli, Silla, Majaj, & Pelli |
Complexity impairs efficiency in the periphery |
| 506 |
Graf & Bülthoff |
Shape transformations and image-plane rotations in object categorization |
| 507 |
Downing, Dodds, Chan, & Turnbull |
Strong category-selectivity is rare in human visual cortex |
| 508 |
Georgieva, Todd, Pieters, & Orban |
Cortical Regions Involved in Extracting 3D Shapes from Shading |
| 509 |
Baker & Olson |
Automatic processing of whole objects in a part identification task |
| 510 |
Lalchandani, Loula, & Carrasco |
Temporal dynamics of negative priming |
| 511 |
Allred, Thompson, & Jagadeesh |
Color-based estimates of stimulus similarity predict perceptual similarity of image pairs to monkeys |
| 512 |
Anes & Storbeck |
Does a consistent rotational representation facilitate responding to test probes further along a rotational sequence? |
| 513 |
Sadr & Sinha |
Characterizing object-specific neural correlates of perception |
| 514 |
Kayaert, Vogels, & Biederman |
The effect of asymmetry and complexity on the sensitivity of inferior temporal neurons to nonaccidental differences |
| 515 |
Grill-Spector, Knouf, & Kanwisher |
The fusiform face area is significantly correlated with successful detection andidentification of faces but not objects |
| Natural Images |
516 |
Hansen & Essock |
Human visual processing of orientation and the slope of the amplitude spectra of natural stimuli |
| 517 |
Essock & Hansen |
Seeing the content before the horizon: Visual processing of orientation in natural scenes |
| Perceptual Organization |
518 |
Purves, Howe, & Schwartz |
Vision and the perception of music have a common denominator |
| Natural Images |
519 |
Gegenfurtner, Braun, & Wichmann |
The importance of phase information for recognizing natural images |
| 520 |
Johnson & Baker |
Response of first- and second-order filters to natural images |
| 521 |
Stringer & Dong |
Visual input statistics of natural time-varying images for different viewers, scenes, spectra and illuminations |
| 522 |
Howe & Purves |
Size contrast explained by the statistics of scene geometry |
| 523 |
Fine & Boynton |
Do observers use the mean, the median or the mode? |
| Motion 3: Low-level, Time, Biological |
524 |
Hale & Pollick |
Visual analysis of movements generated by biomimetic motor-production criteria and displayed via computer animations and humanoid robots |
| 525 |
Lestou, Pollick, Bülthoff, & Kourtzi |
The involvement of parietal and prefrontal areas in human imitation revealed by fMRI adaptation |
| 526 |
Hiris & Humphrey |
The effect of temporal incoherence between mask and point light walker on the detection of biological motion |
| 527 |
McAleer, Fidopiastis, Braden, & Pollick |
Obtaining features for the recognition of human movement style |
| 528 |
Hittle & Hiris |
Does density explain how moving dots mask biological motion? |
| 529 |
Thompson & Mather |
Discriminating the biological motion of animals |
| 530 |
Lewis, Bhagirath, Ellemberg, & Maurer |
Greater immaturity in sensitivity to second-order gratings than to first-order gratings during infancy |
| 531 |
Edwards & Nishida |
Interaction between first- and second-order motion signals at the local motion scale |
| 532 |
Allen, Hess, & Ledgeway |
Discriminating the direction of randomly positioned contrast-defined motion |
| 533 |
Syed & Tripathy |
Effects of jitter and displacement size on performance in random dot kinematograms |
| 534 |
Hock & Gilroy |
The perception of apparent motion between two element locations depends on the multiplicative combination of background-relative luminance changes |
| 535 |
Raghunandan, Visco, & Stevenson |
Contrast interactions in two-frame motion discrimination imply a binocular site of contrast gain control for motion |
| 536 |
Heinrich, Schilling, & Bach |
Do motion onsets affect motion adaptation? |
| 537 |
Price & Ibbotson |
Phantom and concrete motion aftereffects have different temporal tuning |
| 538 |
Simpson, Falkenberg, & Manahilov |
A "hard threshold" in detection, summation, and direction discrimination? |
| 539 |
Murakami |
Equivalent noise in relative- and absolute-motion detection for pattern translation with artificial jitter |
| 540 |
Souman, Wertheim, & Hooge |
Motion perception and localization during smooth pursuit eye movements |
| 541 |
Li, Sweet, & Stone |
Effect of contrast on the active control of a moving line |
| 542 |
Nijhawan & Khurana |
The flash-lag effect during voluntary and involuntary limb movements |
| 543 |
McBeath, Sugar, Thompson, & Mundhra |
Catching ground balls: Optical control heuristics used by humans and robots support a unified fielder theory |
| 544 |
Choi & Scholl |
Effects of grouping and attention on the perception of causality |
| 545 |
Maimon & Assad |
Neuronal activity in parietal cortex during active control of a moving stimulus |
| Locomotion |
546 |
Lew, O'Leary, & Philbeck |
Nonvisual walking is robustly biased by walking direction |
| 547 |
Flanagan, May, & Dobie |
The effects of visual information on postural stability in dynamic motion environments |
| 548 |
Kitazaki & Kurose |
Postural sway from combined optical flow of radial and lateral motions |
| 549 |
Tyrrell, Wood, Carberry, Faulks, & Jones |
On-road measures of the visibility of pedestrians at night |
| 550 |
Foo, Warren, & Tarr |
Human shortcut performance in a structured maze environment |
| 551 |
Wilkie & Wann |
The stages of steering |
| 552 |
Macuga, Loomis, & Beall |
Perception of heading without optic flow |
| 553 |
Wang |
Learning and Unlearning Spatial Relationships during Navigation |
| 554 |
Chouchourelou, Loula, & Shiffrar |
Meaning influences the perception of apparent human motion |
| 555 |
Fajen & David |
Speed information and the visual control of braking to avoid a collision |
| 556 |
Wann & Wilkie |
The role of gaze fixation in locomotor control |
| 557 |
Fox & Durgin |
More recalibration of the perception of linear self-motion |
| 558 |
Turano, Eisinger, Lei, & Chaudhury |
Egocentric representation affected by target context and head/eye poistions more so for women than for men |
| Attention 3 |
559 |
Puhakka, Häkkinen, & Laarni |
Does preknowledge of target depth affect visual processing? |
| 560 |
Sahraie, Milders, & Niedeggen |
Transient blindness to disparity defined depth |
| 561 |
Barrett & Rose |
The spatio-temporal constraints of object-based priming |
| 562 |
Dosher, Liu, Blair, & Lu |
The spatial footprint of the perceptual template |
| 563 |
Matsumoto, Tanaka, Misaki, & Miyauchi |
The leftward spatial bias exists in the estimation of the subjective midpoint without visual information |
| 564 |
von Muhlenen |
The role of memory in static and dynamic visual search |
| 565 |
Brockmole, Boot, & Simons |
An auditory secondary task modulates attention capture in visual search |
| 566 |
Palix, Ibañez, Hauert, & Leonards |
The influence of target position and response hand on efficient feature search |
| 567 |
Most, Chun, & Widders |
Selective substitution: Attentional set modulates object substitution masking |
| 568 |
Menneer, Barrett, Phillips, Donnelly, & Cave |
The breakdown of efficient search when either of two colour targets can appear |
| 569 |
Gobell, Tseng, & Sperling |
Investigating the spatial modulation transfer function of attention - distinguishing between effects of false target crowding and spatial frequency |
| 570 |
Lanyon & Denham |
A biased competition computational model of spatial and object-based attention mediating active visual search |
| 571 |
Franconeri & Simons |
Searching for stimulus-driven shifts of attention |
| 572 |
Wolfe, Treisman, & Horowitz |
What shall we do with the preattentive processing stage: Use it or lose it? |
| 573 |
Imaruoka & Miyauchi |
Are the singleton-processing brain activities contingent on attentional set? |
| 574 |
Belopolsky, Theeuwes, & Kramer |
Prioritization by visual transients in search: Evidence against the visual marking account of the preview benefit |
| 575 |
Galera & von Grünau |
Size and shape of the attentional spotlight affect efficiency of processing |
| 576 |
Reddy, Wilken, & Koch |
Face-gender discrimination is possible in the near-absence of attention |
| 577 |
Moore & Lleras |
Object-token individuation protects targets from object substitution masking |
| 578 |
Yi, Chun, & Woodman |
Object Substitution Masking Does Not Spread within a Perceptual Group |
| 579 |
Epstein, Hon, & Duncan |
Neural signature of consciously-perceived visual events |
| 580 |
Dennis & Annan |
Can visual objects be accessed in rapid counting without their positions being encoded? |
| 581 |
Kushnier & Pylyshyn |
Can flashing objects grab visual indexes in multiple object tracking? |
| 582 |
Leonard & Pylyshyn |
Measuring the attentional demand of multiple object tracking (MOT) |
| 583 |
Keane & Pylyshyn |
Does tracking disappearing objects in MOT involve predicting the locus of reappearance? |
| 584 |
Suganuma & Yokosawa |
Items in MOT are easily lost when they chase each other |
| 585 |
Pylyshyn & Leonard |
Inhibition of nontargets during multiple object tracking (MOT) |
| 586 |
vanMarle & Scholl |
Attentive tracking of objects vs. substances |
| 587 |
Varakin & Levin |
The relationship between incidental and intentional change detection and long-term recognition |
| 588 |
Orbach & Henderson |
Are there event-related potential (ERP) correlates of implicit change detection? A miscuing paradigm |
| 589 |
Levin & Varakin |
Failure to detect brief disruptions to visual events |
| 590 |
Pardhan, Tiippana, Nasanen, & Bhudia |
Spatial cueing with and without distractor on contrast thresholds for face recognition |
| 591 |
VanRullen, Reddy, Li, Perona, & Koch |
A neural framework for visual attention |
| 592 |
Buttle, Ball, Zhang, & Raymond |
Semantic repetition blindness: Picture versus word effects |
| 593 |
Fernandez-Duque & Black |
Visuo-perceptual abilities in patients with atypical Alzheimer's Disease |
| Adaption/Aftereffects |
594 |
Jacobson, Eagleman, & Sejnowski |
Explaining why the perceived brightness of a flash is modified by temporal relationships with its neighbors: the commitment, adaptation, and comparison model |
| 595 |
Suzuki & Grabowecky |
Pre-adaptation effects in multistable binocular rivalry |
| 596 |
Sayres & Grill-Spector |
Parameters that affect adaptation in the human visual system |
| 597 |
Fang & He |
Weak motion aftereffect from a square wave test |
| 598 |
Moradi & Shimojo |
Multiplicative and suppressive effect of sustained and transient edge adaptation in peripheral target detection |
| 599 |
Francis & Schoonveld |
Interactions of afterimages for orientation and color: New results force model revisions |
| 600 |
Kouhsari & Rajimehr |
Attention dependent illusory line-tilt aftereffect |
| 601 |
Bilson, Fry, Moore, & Webster |
Phase-specific interactions in the perceived blur of edges |
| 602 |
Goltz, Tweed, Menon, & Vilis |
Afterimages and pursuit: refining Helmholtz’s theory of visual motion perception |
| 603 |
von Grunau & MacKinnon |
Simultaneous monocular and binocular motion aftereffects for radial flowfield stimuli |
| 604 |
Gray & Regan |
Visual motion adaptation can impair decision making in driving |
| 605 |
Rajimehr |
Color-contingent orientation adaptation for unresolvable Gabor patches |
| 606 |
Goolsby, Grabowecky, & Suzuki |
Further investigations of the distractor color preview effect (DCPE) |
| 607 |
Becker, Fournier, Vavrek, Bickler, Wiediger, & Patterson |
Cyclopean Motion Processing Does Not Depend Exclusively Upon Selective Attention |
| 608 |
Stephens, Dannemiller, & Diebel |
Contrast decruitment is reduced in matching procedure |
| Texture |
609 |
Katkov, Tsodyks, & Sagi |
Separating signal from noise in visual discrimination |
| 610 |
Phillips & Todd |
Local and global coherence in two and three dimensional textures |
| 611 |
Todd, Thaler, & Dijkstra |
The effects of visual angle on the perception of 3D curvature from texture |
| 612 |
Interrante, Kim, & Hagh-Shenas |
Shape categorization from texture |
| 613 |
Ellemberg, Allen, & Hess |
Spatial lateral interactions operate over shorter distances for second-order compared to first-order mechanisms |
| 614 |
Motoyoshi & Kingdom |
Energy-frequency analysis reveals orientation-opponent channels in human vision |
| 615 |
Wolfson & Graham |
Exploring the opponent structure of complex (second-order) channels |
| 616 |
Harasawa & Sato |
The critical factor for performance improvement in multi-frame orientation texture segregation |
| 617 |
Pei, Hou, & Norcia |
Texture thresholds in aults and infants |
| 618 |
Manahilov, Simpson, & Calvert |
Internal noise and sampling efficiency in discrimination of second-order patterns |
| Synesthesia |
619 |
Witthoft & Winawer |
Casting shadows on synesthesia |
| 620 |
Kim, Blake, Palmeri, Marois, & Whetsell |
Synesthetic colors act like real colors and interact with real colors |
| 621 |
Hubbard, Ramachandran, & Boynton |
Cortical cross-activation as the locus of grapheme-color synesthesia |
| Search |
622 |
Ipata, Krishna, Bisley, Gottlieb, & Goldberg |
Saccadic behavior in Rhesus monkeys performing a visual search task |
| 623 |
McSorley & Findlay |
The eyes can search large displays more effectively than small ones: an oculomotor paradox? |
| 624 |
Najemnik & Geisler |
Optimal visual search |
| 625 |
Chen & Zelinsky |
How "visual" is visual search? Dissociating visual from categorical factors in a search task |
| 626 |
Peterson, Boot, & Kramer |
Environmental cues modulate memory during visual search |
| 627 |
Sireteanu, Bachert, Planert, & Pröhl |
Visual preferences in early infancy are distinct from adult preferences |
| 628 |
Panagopoulos, von Grunau, & Galera |
Intruder effects in cued visual search |
| 629 |
Oh & Kim |
The guidance effect of working memory load on visual search |
| 630 |
Rosenholtz |
Search isocontours as a tool for understanding visual search |
| 631 |
Becker & Pashler |
Searching a noisy visual display with preview |
| 632 |
Davis, Shikano, Peterson, & Michel |
Searching for the gap - comparing young and older adults |
| 633 |
Rensink & Cavanagh |
Constraints on the rapid interpretation of cast shadows |
| 634 |
Birnkrant, Wolfe, & Mendoza |
Is opacity a basic feature? It’s not transparent |
| 635 |
Schiller, Carvey, Kendall, & Slocum |
What the presentation of two visual targets with varied contrasts, sizes and temporal asynchronies tells us about the process of target selection in humans and monkeys |
| Scene Perception |
636 |
Fermuller |
Statistical bias predicts many illusions |
| 637 |
Kingdom, Beauce, & Hunter |
Colour vision brings clarity to shadows |
| 638 |
Jenkin, Dyde, Zacher, Jenkin, & Harris |
Multi-sensory contributions to the perception of up: Evidence from illumination judgements |
| 639 |
Behizadeh, Vessel, & Biederman |
Verifying objects in minimal scenes |
| 640 |
Walter, Bala, & Dassonville |
Explicit and implicit priming in change detection |
| 641 |
Gottesman |
Viewpoint changes affect priming of spatial layout |
| 642 |
Sanocki, Michelet, & Sellers |
How are elements of a scenic layout bound together? |
| 643 |
New |
A content-specific attenuation of change blindness: Preferential attention to animate beings in natural scenes |
| 644 |
Zelinsky & Loschky |
Fuzzy object file theory: A framework for understanding recency effects for objects in scenes |
| 645 |
Feria, Braunstein, & Andersen |
Judging distance across discontinuities in the frontal plane |
| 646 |
Eklundh, Bjorkman, & Hayman |
Object appearance from integration of 3D and 2D cues in real scenes |
| 647 |
Velisavljevic & Elder |
Eccentricity effects in the rapid visual encoding of natural images |
| 648 |
Bian, Braunstein, & Andersen |
Local and global texture effects on judged distance in a 3-D scene |
| 649 |
O'Donnell & Langton |
Gaze cues attenuate change blindness in the flicker paradigm |
| Perceptual Organization |
650 |
Olzak & Gabree |
Relative effects of superimposed and lateral masks in discrimination |
| 651 |
Saylor & Olzak |
Do lateral influences in discrimination cross segmentation boundaries? |
| 652 |
Chen & Tyler |
Mapping psychophysical non-classical receptive field with dual masking experiments |
| 653 |
Strasburger |
A generalized cortical magnification rule predicts low-contrast letter recognition in the visual field |
| 654 |
Barghout, Palmer, & Tyler |
Masking by edge-induced illusory contours depends on contrast polarity |
| 655 |
Santos, Simas, & Nogueira |
Comparing contrast sensitivities to angular frequency stimuli and sinewave gratings in aged |
| 656 |
Spillmann, Pinna, Stürzel, & Werner |
Extraretinal factors required for visual illusions |
| 657 |
Shubel & Gold |
The time course of visual completion measured by response classification |
| 658 |
Wang & Hess |
Integration of local orientational and positional contour features in shape discrimination |
| 659 |
Xing |
The intrinsic differences of lateral interactions in fovea and periphery and their functional impacts on visual perception |
| 660 |
Tse & Gerhardstein |
Simulating the development of contour integration |
| 661 |
Shipley & Kellman |
Retinal anisotropies in illusory contour formation |
| 662 |
Carlo & Walter |
T-junction geometry and angle completion |
| 663 |
Biederman, Vessel, & Greene |
The grouping of contours into an L-Vertex depends on contrast polarity: Evidence for the incorporation of image statistics into mechanisms of perceptual grouping |
| 664 |
Feldman, Singh, Barenholtz, & Cohen |
A psychophysical window onto the mental representation of shape |
| 665 |
Koning & van Lier |
Global cues affect the apparent misalignment in the Poggendorff Illusion |
| 666 |
von der Heydt, Qiu, & He |
Neural mechanisms in border ownership assignment: motion parallax and gestalt cues |
| 667 |
Palomares, Landau, Egeth, & Hoffman |
Collinear inhibition in Williams Syndrome? |
| Perceptual Learning |
668 |
Rasche, Pham, & Eckstein |
The influence of stimulus information on human perceptual learning: An ideal observer analysis |
| 669 |
Poggel, Mueller-Oehring, Gothe, Kenkel, Kasten, & Sabel |
Pseudo-hallucinations in patients with visual field defects during spontaneous and training-induced recovery |
| 670 |
Petrov, Dosher, & Lu |
A computational model of perceptual learning through incremental channel re-weighting predicts switch costs in non-stationary contexts |
| 671 |
Welch & Boachie |
Learning a novel 3D object category |
| 672 |
Dupuis-Roy & Gosselin |
Perceptual learning without signal |
| 673 |
Bouvrie & Sinha |
Object concept learning from non-normalized data |
| 674 |
Blair, Dosher, & Lu |
Evaluation of token specificity in perceptual learning of phase discrimination |
| 675 |
Zaenen, Willems, & Wagemans |
Dissociating perceptual and other factors affecting the matching method: line orientation and slant estimation |
| 676 |
Copeland & Wenger |
Investigating perceptual and decisional mechanisms for the dynamics of perceptual learning: Theory, models, and data |
| 677 |
Silverman & Welch |
Does chunking by color facilitate category learning? |
| 678 |
Bruggeman, Eid, Rieser, & Pick |
Alteration of the direction of throwing; multiple levels of adaptation |
| Memory |
679 |
Zhou, Kahana, & Sekuler |
Episodic short-term memory for spatial frequency: Is a series of stimuli remembered as a single prototype or as distinct exemplars? |
| 680 |
Conte & Victor |
Temporal stability of image statistics in visual working memory |
| 681 |
Zhang & Luck |
Slot-like versus continuous representations in visual working memory |
| 682 |
Vandenbeld & Rensink |
The decay characteristics of size, color, and shape information in visual short-term memory |
| 683 |
Yotsumoto, Wilson, Kahana, & Sekuler |
Episodic recognition memory for high-dimensional, human synthetic faces |
| 684 |
Morikawa & Mel |
Sex differences in binding color to spatial location in picture recognition memory |
| Eye Movement Cognitive |
685 |
Harwood, Madelain, Krauzlis, & Wallman |
Spatial scale of attention strongly modulates saccade latency, but not by modulating stimulus saliency |
| 686 |
DeSouza, Iversen, & Everling |
Neural correlates for preparatory set associated with pro-saccades and anti-saccades in primate prefrontal cortex |
| 687 |
Li & Yoon |
Errors in exocentric localization during pursuit eye movement: the effect of spatiotemporal properties of a static reference |
| 688 |
Heidenreich & Turano |
What predicts where one will look when viewing artwork? |
| 689 |
Gottlob |
Eye movements and response accuracy in comparative visual search |
| 690 |
Johnson, Amso, & Slemmer |
Development of object concepts in infancy |
| 691 |
Prime, Niemeier, Yan, & Crawford |
Trans-saccadic Integration for Low-level Visual Information |
| 692 |
Maeda, Ando, & Sugimoto |
The spatial deviation of reaching to the same point under the different gaze directions |
| 693 |
Mccarley, Kramer, Boot, & Colcombe |
Automatic and intentional memory processes in saccade target selection |
| 694 |
McPeek & Keller |
The effects of reversible inactivation of Frontal Eye Field and Superior Colliculus on saccade target selection |
| 695 |
Watanabe, Maeda, & Tachi |
The time course of localization errors for repeatedly flashing stimuli through a saccade |
| 696 |
Boucher, Fendrich, & Hughes |
Cues to the relative spatial locations of visual targets presented in the dark |
| 697 |
Greenlee, Oezyurt, Rutschmann, & Vallines |
Event-related fMRI of saccadic response inhibition |
| 698 |
Przybyszewski, Kagan, & Snodderly |
Eye position influences contrast responses in V1 of alert monkey |
| 699 |
Sheliga & Miles |
Perceived slant influences vergence responses during horizontal gaze shifts across a surface |
| 700 |
Niemeier, Crawford, & Tweed |
A new form of saccadic compression of space |
| Color |
701 |
Monnier & Shevell |
Color shifts from patterned backgrounds: Spatial frequency selectivity and contrast sensitivity |
| 702 |
Hillis & Brainard |
Cone inputs controlling color context effects: Detection and appearance |
| 703 |
Wu, Kanai, & Shimojo |
Color-spreading selective for shape and configuration |
| 704 |
Young & Nagy |
Combining information about color and line length in visual search |
| 705 |
Neriani & Nagy |
Combining information in different color mechanisms in visual search |
| 706 |
Ortega & Mel |
Color constancy as probabilistic inference: managing the tradeoff between the illuminant prior and scene evidence |
| 707 |
Wolf & Hurlbert |
Attentional modulation of simultaneous chromatic contrast |
| 708 |
Shady, MacLeod, Mitten, & Liang |
A failure of the talbot-plateau law: temporally asymmetric chromatic flicker |
| 709 |
Kiper, Mandelli, & Cardinal |
Chromatic selectivity of the mechanisms underlying object detection and color categorization |
| 710 |
Lindsey & Brown |
Detection of chromatic gratings in noise: field sensitivity and additivity within chromatic channels |
| 711 |
Winawer, Witthoft, Wu, & Boroditsky |
Effects of language on color discriminability |
| 712 |
Civan, Teller, & Palmer |
Infant Color Vision: Spontaneous preferences versus novelty preferences as indicators of chromatic discrimination among suprathreshold stimuli |
| Attention 4 |
713 |
Yoshida, Ashida, & Osaka |
Reaction time reveals that visual search has more memory |
| 714 |
Nieuwenstein, Hooge, & Van der Lubbe |
The attentional blink reflects a delay in selecting T2 for working memory consolidation |
| 715 |
Woodman & Chun |
Access to visual working memory is required for contextual cueing in visual search |
| 716 |
Jolicoeur & Stevanovski |
Visual short-term memory encoding requires central capacity |
| 717 |
Saiki |
Perception and memory in a spatiotemporal visual search |
| 718 |
Carter, Brown, Breitmeyer, & Havig |
Allocation of attention affects the time-course of metacontrast masking |
| 719 |
Skaar, Rizzo, & Stierman |
Glare disability with attention impairment |
| 720 |
Lee, Sato, & Park |
Intact task switching in schizophrenia with a novel Arrow-Stroop task |
| 721 |
Richards, Bennett, & Sekuler |
The time course of the useful field of view: The effects of aging and learning |
| 722 |
Sifrit, Chaparro, & Stumpfhauser |
Reversal of age-related deficits in visual attention: How long do the gains last? |
| 723 |
Sheffield, Rizzo, & Vecera |
Increased reliance on attentional precues in normal aging |
| 724 |
Rogers, Chaparro, & Rogers |
Effect of an attention demanding visual task on postural control in young and old adults |
| 725 |
Orprecio & Adler |
Visual pop-out in infancy: Effects of set-size on the latency of their eye movements |
| 726 |
Shapiro & Garrad-Cole |
Age-related deficits and involvement of frontal cortical areas as revealed by the attentional blink task |
| 727 |
Saenz & Boynton |
The role of competing stimuli in feature-based attention |
| 728 |
Kawahara, Enns, & Di Lollo |
Task-set is vulnerable to exogenous resetting during target identification |
| 729 |
Beck & Levin |
The Guidance of Visual Attention: Using and Acquiring Knowledge about the Probability of Change |
| 730 |
Huang, Dobkins, & Pashler |
Contrast in visual selective attention: just another feature? |
| 731 |
Chiba & Yokosawa |
Midstream order deficit in phonological encoding |
| 732 |
Crewther, Rutkowski, & Crewther |
Change detection is impaired in poor readers for both letter and object targets |
| 733 |
Baldassi & Verghese |
Effect of location and feature cues on the masking function for location |
| 734 |
Ling & Carrasco |
Sustained and transient covert attention: A test for signal enhancement |
| 735 |
Mounts |
The role of attentional salience in localized attentional inhibition |
| 736 |
Li & Yeh |
Role of dynamic transients in attentional capture by irrelevant onsets |
| 737 |
Annan & Pylyshyn |
Voluntary indexing requires serial visitation |
| 738 |
Marois, Todd, & Gilbert |
Surprise Blindness: A distinct form of attentional limit to explicit perception? |
| 739 |
Kimura, Miura, Doi, & Yamamoto |
Top-down and Bottom-up controls of attention in three-dimensional space when observers are moving forward |
| 740 |
Ciaramitaro & Glimcher |
Exploring the temporal dynamics of shifts in spatial attention with changing subject certainty |
| 741 |
Matsubara, Nakazawa, Hama, Shioiri, & Yaguchi |
Control of the location and extent of visual attention |
| Temporal Processing |
742 |
Cho & Francis |
Backward masking with sparse masks: Models and experiments |
| 743 |
Lawson, Booth, Burns, Davis, Fuller, Labropoulos, Thorneycroft, & Crewther |
Investigating the relationship between performance on the Attentional Blink and Change Detection tasks |
| 744 |
Bhattacharya, Watanabe, & Shimojo |
Role of nonlinear brain dynamics as a defensive mechanism against photosensitivity |
| 745 |
Wilmer |
Individual Differences in Dynamic Visual Processing |
| 746 |
Chu, Lu, & Dosher |
Characterizing and modeling temporal dynamics of perceptual decision making |
| 747 |
Pratesi, Emanuela, Pellegrini, & Marzi |
Interhemispheric Transfer as assessed with the Poffenberger paradigm: What kind of signal is transferred? |
| 748 |
Yokosawa, Niimi, & Watanabe |
Temporal characteristics of bilateral symmetry perception: Predominant effect of visible persistence |
| 749 |
Miyawaki & Okada |
Computational model of transcranial magnetic stimulation: temporal property and subthreshold prolongation of visual suppression induced by neural population |
| 750 |
Makous, Rainville, & Chen |
Serial temporal filters in human vision |
| 751 |
Kopinska, Harris, & Lee |
Comparing central and peripheral events: compensating for neural processing delays |
| 752 |
Santella & Carrasco |
Perceptual consequences of temporal disparities in the visual field: The case of the line motion illusion |
| Perceptual Organization |
753 |
Rainville & Wilson |
Motion constraints on the integration of spatial cues into global form |
| 754 |
Macuda, Johnston, & Timney |
A direct estimate of the size of the illusory spots in the Hermann Grid Illusion |
| 755 |
Meng, Remus, & Tong |
Effects of perceptual grouping in human primary visual cortex |
| 756 |
Poirier & Frost |
A parallel binding solution via separate integration and segregation mechanisms |
| 757 |
Yazdanbakhsh & Grossberg |
How does perceptual grouping synchronize quickly under realistic neural constraints? |
| 758 |
Chang & Yeh |
Grouping by color similarity, orientation similarity and collinearity under conditions of inattention |
| 759 |
de Wit & van Lier |
Investigating visual completion: the visual search paradigm versus the change detection paradigm |
| 760 |
Barenholtz, Cohen, Feldman, & Singh |
Non-accidental properties and change detection |
| 761 |
Meng & Qian |
The oblique effect depends on the perceived, rather than physical, orientation and direction |
| 762 |
Collin, Large, & McMullen |
Forest, Trees and Leaves: Interference Effects in 3-Level Navon Figures |
| 763 |
Vecera, Flevaris, & Filapek |
Exogenous spatial attention influences figure-ground assignment |
| 764 |
Nelson |
Attention and Figure/Ground Segregation |
| 765 |
Shani & Sagi |
Attention uncovers peripheral collinear facilitation |
| 766 |
Kimchi & Razpurker-Apfeld |
Perceptual Grouping and Attention |
| 767 |
McAnany & Levine |
The Blanking Phenomenon and its Psychoanatomical Implications |
| 768 |
Tong & Seiffert |
A luminance-based mechanism mediates active filling-in of the blind spot |
| 769 |
Lleras & Enns |
Negative compatibility in masking: unconscious inhibition or new feature priming? |
| Multimodal: Touch, Sound, & Integration |
770 |
Newton, Ellsworth, Miyakawa, Tonegawa, & Sur |
C-fos expression and accelerated visual cued fear conditioning in mice with visual input directed to the auditory thalamus |
| 771 |
Wuerger, Roehrbein, Meyer, Hofbauer, Schill, & Zetzsche |
Auditory and visual motion signals have to be co-localized to be effectively integrated |
| 772 |
Kobayashi & Osada |
The cross- modal effect of perceptual organization of sounds on the visual target detection |
| 773 |
Geiger, Ezzat, & Poggio |
Explicit and implicit perceptual discrimination of videorealistic speech |
| 774 |
Chee-Ruiter, Neil, Scheier, Lewkowicz, & Shimojo |
Development of multimodal spatial integration and orienting behavior in humans |
| 775 |
Barutchu, Crewther, Paolini, & Crewther |
The effects of modality dominance and accuracy on motor reaction times to unimodal and bimodal stimuli |
| 776 |
Sheth & Shimojo |
A moving visual stimulus progressively drags the perceived timing of a sound |
| 777 |
Kim, Pasieka, & McCourt |
Auditory "capture" of visual motion |
| 778 |
Norman, Norman, Clayton, Lianekhammy, & Zielke |
The visual and haptic perception of natural object shape |
| 779 |
Levitan, Gepshtein, & Banks |
Visual and haptic precision and inter-modal perception of curved surfaces |
| 780 |
Sobel, James, & Blake |
Tactile perception facilitates resolution of visual conflict |
| 781 |
Campos, Young, Chan, Zhang, Ellard, & Sun |
The contributions of nonvisual cues, static visual cues, and optic flow in distance estimation |
| Motion 4: Shape & Depth |
782 |
Straw & O'Carroll |
Motion blur applied to eliminate artifacts in apparent motion displays |
| 783 |
Scott-Samuel |
Differences and similarities in short- and long-range motion processing |
| 784 |
Bukowski, Huisman, Rivera, & Hock |
Perceptual categorization: Dynamical vs. Judgmental boundaries |
| 785 |
Meyer & Shipley |
Perception of curved apparent motion paths |
| 786 |
Paterson & Pollick |
Perceptual consequences when combining form and biological motion |
| 787 |
Hess & Ledgeway |
The spatial properties of motion-defined contours? |
| 788 |
Kamiya & Sato |
Motion-defined checkerboard pattern reverses VEP’s polarity |
| 789 |
Remus & Engel |
Motion from occlusion |
| 790 |
Claeys, Lindsey, De Schutter, Van Hecke, & Orban |
The neural correlate of a higher-order feature-tracking motion system revealed by fMRI |
| 791 |
Graf, Warren, & Maloney |
Extrapolation of motion paths behind an occluder |
| 792 |
McMullen & Collin |
First-Order Translational Motion but not Second-order Form-from-Motion Aids Shape-Identification in Peripheral Vision |
| 793 |
Sauer, Andersen, & Saidpour |
Linearly changing bearing and collision detection of objects traveling on curved 3D trajectories |
| 794 |
Friedrich, Hadjigeorgieva, & Mamassian |
Attentional effects and motion-induced masking |
| 795 |
Loffler, Kennedy, Orbach, & Gordon |
Properties of static and dynamic angle discrimination are different |
| 796 |
Berzhanskaya, Grossberg, & Mingolla |
Object motion from cortical form-motion interaction between V1, V2, MT and MST |
| 797 |
Nawrot |
Translating sound does not affect eye movements or the perception of depth from motion parallax |
| 798 |
Lages, Dolia, & Graf |
Dichoptic motion within Panum's fusional area? |
| 799 |
Stoner, Albright, & Hegde' |
Depth order perception in first- and second-order motion stimuli |
| 800 |
Sieffert & Gray |
Different strategies for using motion in depth information in catching |
| 801 |
Quinlan, Culham, & Goodale |
fMRI investigation of depth specificity in human posterior parietal cortex |
| 802 |
Likova, Tyler, & Wade |
Brain activation during stereomotion perception: An fMRI study |
| 803 |
Maruya & Sato |
Perceptual offset between first- and second-order motion stimulus |
| 804 |
Hegde', Albright, & Stoner |
Contextual effects of binocular depth cues and shadow-based depth cues on motion interpretation |
| 805 |
Mamassian & Wallace |
Depth assignment in motion transparency |
| Letters/Reading |
806 |
Berger, Martelli, Su, Aguayo, & Pelli |
Reading quickly in the periphery |
| 807 |
Thorn, Thorn, & He |
Harry Potter and the spatial spectra in English and Chinese |
| 808 |
Florer, Thompson, & Jadeja |
What type of practice improves reading rates for nonstandard letter spacing: visual or text? |
| 809 |
Wong & Gauthier |
Font tuning differentiates experts and novices in letter recognition |
| 810 |
Brooks, Owens, Stephens, & Tyrrell |
How well do we know our own visual limitations? Comparisons of estimated and actual visual abilities |
| 811 |
Schwartz, Tjan, & Chung |
Spatial-frequency phase noise in central and peripheral vision |
| 812 |
James, Roy, & Gauthier |
Visual perception is affected by motor experience: Evidence from letter recognition |
| 813 |
Majaj, Liang, Martelli, Berger, & Pelli |
Channel for reading |
| 814 |
Fine |
Reduced contrast does not reduce visual crowding |
| 815 |
Chung, Legge, & Ortiz |
Precision of local signs for letters in central and peripheral vision |
| 816 |
Scharff & Ahumada |
Letter identification latencies are predicted by an asymmetric contrast metric |
| Face Perception |
817 |
Jackson & Raymond |
Familiarity effects on face recognition in the attentional blink |
| 818 |
Borrmann, Boutet, & Chaudhuri |
Spatial attention favors faces over non-face objects in an attentional cueing task |
| 819 |
McCabe, Gosselin, & Arguin |
What causes the face inversion effect in a gender priming task? |
| 820 |
Pilz, Thornton, & Bülthoff |
Matching and searching for moving faces |
| 821 |
Curby, Schyns, Gosselin, & Gauthier |
Differential use of spatial frequency scales for face recognition in a person with Asperger’s syndrome |
| 822 |
Paras, Yamashita, Simas, & Webster |
Face perception and configural uncertainty in peripheral vision |
| 823 |
Peissig, Vuong, Harrison, & Tarr |
Contrast reversals in faces and objects: The effect of albedo |
| 824 |
Gaspar, Husk, Sekuler, & Bennett |
The Effect of Information-Spread on Face Discrimination |
| 825 |
Bülthoff & Newell |
Interaction between vision and speech in face recognition |
| 826 |
Rivest, Moscovitch, & Cadieux |
Face identification is dissociable from face imagery and generic face representation |
| 827 |
Grand, Maurer, Mondloch, Duchaine, Sagiv, & de Gelder |
What types of configural face processing are impaired in prosopagnosia? |
| 828 |
Greene, Mangini, & Biederman |
Trying your best to ignore a face does little to diminish the N170 |
| 829 |
Harris, Liu, Duchaine, & Nakayama |
Characterizing face processing in developmental prosopagnosia using magnetoencephalography |
| 830 |
Vinette, Bacon, Gosselin, & Schyns |
What does the N170 respond to in upright versus inverted faces? |
| 831 |
Andalman & Sinha |
The effects of scene clutter on the M170 face response |
| 832 |
Smith, Jentzsch, Gosselin, & Schyns |
A principled method to attribute function to brain signals |
| 833 |
Ward, Stephens, & Dannemiller |
Adult perception of schematic faces that infants prefer |
| 834 |
Cheng & Tarr |
How to rob a bank and get away with it: Recognizing disguised faces |
| 835 |
Honma & Osada |
The effect of the dynamic property on the recognition of moving facial |
| 836 |
Yue, Mangini, & Biederman |
A psychophysical investigation of the other race effect in face recognition |
| 837 |
Schwaninger, Wallraven, Schuhmacher, & Buelthoff |
News on facial views from humans and machine |
| 838 |
Vickery & Gauthier |
Keeping a straight face: configural processing and the aperture capture illusion |
| 839 |
Zhu & Cutu |
Face Detection using Half-Face Templates |
| Depth/3D Shape |
840 |
Adams & Mamassian |
Bayesian combination of ambiguous shape cues |
| 841 |
Li & Zaidi |
Perception of 3-D carved surfaces from monocular texture cues |
| 842 |
Rosas & Wagemans |
Combination of texture and object motion in slant discrimination |
| 843 |
Hecht & Anes |
Does a simple shading manipulation lead to size overestimation in 3-D volumes? |
| 844 |
Ichikawa |
Perceived time order for the stimuli presented at different depth is event-dependent |
| 845 |
Ando |
Internal representation of gravity for visual prediction of an approaching 3D object |
| 846 |
Yonas, Alexander, & Jacques |
Actions of 9-month-old infants directed at real toys, photographed toys, and surfaces |
| 847 |
Warren & Mamassian |
The dependence of slant perception on texture orientation statistics |
| 848 |
Burge, Hillis, Landy, & Banks |
Disparity and texture gradients are combined in two ways |
| 849 |
Griffiths & Zaidi |
Misperception of symmetries in partitionable shapes |
| 850 |
Welchman, Deubelius, Maier, Bülthoff, & Kourtzi |
fMRI correlates of visual cue combination |
| 851 |
Kojo, Häkkinen, & Simola |
Depth capture in a natural environment |
| 852 |
Wilcox, Wildes, & Lakra |
Depth ordering in natural stereoscopic images: The role of monocular occlusion |
| 853 |
Sakano, Matsumiya, & Kaneko |
Effects of viewing distance and experience on the integration process of disparity and perspective for the slant perception |
| 854 |
Matsushima, Ribeiro-Filho, & Silva |
Increasing the range of self-generated motion parallax increases its effectiveness |
| Depth & Motion |
855 |
Jimenez-Ortega & Troje |
Differential motion parallax as a monocular depth cue? |
| 856 |
Shioiri, Kakehi, Tashiro, & Yaguchi |
Investigating perception of motion in depth using monocular motion aftereffect |
| 857 |
Brooks & Stone |
Spatial scale of stereomotion processing from changing disparity signals |
| 858 |
Zhong & Braunstein |
Effect of background motion on perceived object shape |
| 859 |
Dean, Tuck, & Harris |
Percieved direction of binocular 3-D motion when tracking a moving object |
| 860 |
Gamphe & Gamlin |
The Duncker illusion affects the perception of targets moving in depth |
| Attention 5 |
861 |
Brown & Solberg |
Detecting changes in spatial frequency: Exploring the interaction of object- and space-based visual processing |
| 862 |
Pestilli & Carrasco |
Contrast sensitivity is enhanced at cued and impaired at uncued locations |
| 863 |
Lu, Tse, Dosher, Lesmes, Posner, & Chu |
Intra- and cross-modal cuing of visual spatial attention: The hyper-effective simultaneous auditory peripheral cues |
| 864 |
Rezec, Krekelberg, & Dobkins |
Effects of attention and contrast on motion processing |
| 865 |
Sohn, Papathomas, Blaser, & Vidnyánszky |
Object-based cross-attribute attentional effects in bivectorial motion |
| 866 |
Dannemiller |
A dimensional switching model of early visual orienting in human infants |
| 867 |
Del Vecchio & von Grünau |
Comparison of two methods for equating the salience of first- and second-order motion |
| 868 |
Seiffert |
Dissociating neural correlates of attentional tracking and attention to visual motion |
| 869 |
Tseng, Gobell, & Sperling |
Attentional sensitization to specific colors |
| 870 |
Hibi & Yokosawa |
Relationship between response blocking and task switching |
| 871 |
Crewther, Crewther, & Cook |
Saccadic eye-movements reduce but do not eliminate the line-motion illusion |
| 872 |
Reeves, Fuller, & Fine |
Attention helps one acquire novel color/shape combinations |
| 873 |
Jeon, Lu, & Dosher |
Temporal tuning characteristics of perceptual templates |
| 874 |
Grabowecky & Suzuki |
Selective attention during adaptation weakens negative afterimages |
